RU2191965C1 - Gear to decelerate recoil of small arms - Google Patents

Abstract

FIELD: small arms, devices reducing recoil. SUBSTANCE: gear to decelerate recoil of small arms has cylinder with front wall spring-loaded and mounted on barrel and piston, barrel has gas-removing conduits. Gear also includes cylindrical enclosure with rear wall and front face, barrel can travel with reference to enclosure that is coupled to cylinder and embraces it and front part of barrel protruding from it which has front gas-dynamic blade and at least one additional blade. Each blade has C-shaped radial section with convexity facing outlet hole of barrel and forms ring chamber with enclosure. Each additional blade is provided with overflow window, gas-removing conduits of barrel are inclined at some angle with reference to axis of barrel with angle vertex facing inlet hole f barrel and communicate space of barrel with proper ring chambers. Cylinder has scavenging ducts in front wall and piston is immobile with regard to barrel. EFFECT: enhanced efficiency of weapon due to reduced energy of recoil. 12 cl, 8 dwg

Description

 The invention relates to a rifle mainly automatic and more particularly to muzzle devices to reduce recoil.

 A device is known for braking the recoil of small arms, comprising a cylinder movably mounted on the barrel and spring-loaded relative to it with a front wall and purge holes in the side walls and a piston, and the barrel is made with gas channels (see RU 2138000 C1, 09.20.1999, F 41 A 21 / 36).

 A disadvantage of the known device is the relatively low efficiency of reducing recoil energy.

 The technical result is to increase the efficiency of the device by reducing the recoil energy, allows the damping of the inertial forces of the recoil pulse, the visible spectrum of the flame and the sound of the shot, as well as the ventilation and cooling of the barrel.

 The technical result is achieved by the fact that the device for braking the recoil of small arms contains a cylinder spring-loaded relative to the barrel with a front wall and purge holes in the side walls and a piston, and the barrel is made with gas channels, it is equipped with a cylindrical casing with a rear wall and a front end, the piston is rigidly connected with the barrel, which has the ability to move relative to the casing, which is connected with the cylinder and covers it and the front part of the barrel protruding from it, which is made with with a front gas-dynamic blade and at least one additional blade, each of the blades has a C-shaped radial section with a bulge facing the outlet of the barrel and forms an annular chamber, each additional blade has a bypass window, and the gas outlet channels of the barrel connect the barrel cavity to corresponding annular chamber.

 In addition, the cylinder may have purge openings in the front wall.

 In addition, each of the blades can contact its edges with the casing, and the bypass windows of the additional blades can be shifted to the contact zone with the casing.

 The gas outlet channels of the barrel are preferably directed at an angle to the axis of the barrel with the apex of the angle facing the barrel inlet.

 The cylinder can also be made with purge channels in the front wall.

The inner surface of the rear wall of the casing may also have a C-shaped radial section with a bulge facing the inlet of the barrel. Each of the additional blades can have these bypass windows located 90 ^° offset, each annular chamber can be connected to the barrel cavity by four indicated gas channels in the zones between the bypass windows, and the bypass windows of adjacent blades can be shifted relative to each other by 45 ^o . The axis of each gas outlet bore in the radial section is preferably perpendicular to the chord connecting the base of the corresponding blade with the place of its contact with the casing. The cylinder can be made with tides on the outer surface, and each purge hole of the cylinder is located on the inclined surface of the corresponding tide, facing the rear wall of the casing. The connection of the cylinder with the casing can be made in the form of fixing on the end wall of the casing of the rear end of the cylinder, and the cylinder can have overflow windows in the fixing zone. The piston surface facing the rear end wall of the casing may be concave. The spring can be placed in the cavity of the cylinder between its front wall and the piston. The blades are mainly made circular.

 In FIG. 1 shows a General view of the device in section. Figure 2 is a section aa of figure 1. Figure 3 is a section bb In figure 1. Figure 4 is a section CC of figure 1. In FIG. 5 is an enlarged view of the purge channel. Figure 6 is a section D-D of figure 1. In Fig.7 is a section EE of Fig.1. On Fig - section F-F of Fig.1.

 The device contains a cylinder 16 spring-loaded relative to the barrel 7 with a spring 15 and a front wall 20 and a piston 14. The barrel 7 is made with gas channels 1 and has a primary chamber 2. The casing 17 with the rear wall 9 is mounted movably relative to the barrel 7. The front part of the barrel is made with a front gas-dynamic the blade 22 and additional gas-dynamic blades 4, forming with the casing 17 gas-vortex reactive annular chambers 3. The barrel 7 has a gas outlet channels 1 connecting the cavity of the barrel 7 with the corresponding chambers 3. Cylinder 16 made with purge channels 8 in the front wall 20. The cylinder 16 is made with tides on the outer surface, with each purge hole 10 located on the inclined surface of the tide facing the rear wall of the casing 17. The cylinder 16 has bypass ports 12 on the rear end wall of the casing 17 in the zone of consolidation. An expansion chamber 5 is located between the casing 17 and the cylinder 16. The rarefaction chamber 11 is formed by the surfaces of the barrel 7 and the cylinder 16. At the rear wall 9 of the casing 7 there is a secondary chamber 13 connected to the chamber 5 through the bypass windows in the cylinder 16. The device contains a piston stop 18, buffer chipper 19 and frame 21.

Each of the blades 4, 22 has an annular shape and a C-shaped radial section with a bulge facing the outlet of the barrel. The vanes 4, 22 contact their edges with the casing 17. The additional vanes 4 have bypass windows 6 offset to the contact zone with the casing 17. The bypass windows 6 are 90 ^° offset (Fig. 6). Each annular chamber 3 is connected to the cavity of the barrel 7 by four gas outlet channels 1 in the zones between the bypass windows 5, and the bypass windows of the adjacent blades 4 are offset from each other by 45 ^o (Fig.6, 7).

 The gas outlet channels 1 are directed at an angle to the axis of the barrel so that the axis of each channel 1 in a radial section is perpendicular to the chord connecting the base of the corresponding blade 4 with the place of its contact with the casing 17.

 The inner surface of the rear wall 9 of the casing 17 is concave, i.e., a C-shaped radial section with a bulge facing the inlet of the barrel 7, and the surface of the piston 14 facing the rear end wall 9 of the casing 17 is also concave.

 The operation of the device is as follows.

 When fired, when the bullet (projectile), moving along the bore, passes the gas outlet channels 1, the powder mixture rushes through the above channels into the primary chamber 2 and subsequent chambers 3, in which, upon encountering the blades 4, 22, it informs the latter, and at the same time as trunk 7 rigidly connected with them, kinetic energy of its own mass with force vectors directed forward (to the right) (according to the drawing).

 The secondary expansion of the gas-powder mixture occurs in the primary chamber 2, expansion chamber 5 and chambers 3 with regions of maximum pressure on the working (inner) surfaces of the blades 4, 22, the special configuration of which in combination with the direction of the newly arriving gas-powder mixture from the gas outlet channels 1 creates in chambers 3 vortex movement of the gas-air mixture with the direction of rotation counterclockwise (according to the drawing).

 The air-gas mixture after secondary expansion is thrown from the blades 4, 22 of the primary chamber 2 back (to the left) into the expansion chamber 5, and from the blades 4, subsequent chambers 3, through the bypass windows 6 made on the blades 4, through the primary chamber 2 also expansion chamber 5, as a result of which a high pressure region is formed in the rear (left) part of the expansion chamber 5.

 The region of increased pressure on the working surfaces of the blades 4, 22 with the gas being thrown back (to the left) through the bypass windows 6 also creates a reactive moment on the blades 4, 22 with similar force vectors directed to the right, which is transmitted to the barrel 7 rigidly fastened to the gas-dynamic blades.

 The maximum pressure, speed and duration of the expiration of the gas-powder mixture falls on the first row of channels 1 connecting the channel of the barrel 7 with the primary chamber 2.

 The purge channels 8 connecting the rarefaction chamber 11 to the primary chamber 2 are designed so that their front part fits directly to the nozzles of the gas outlet channels 1 of the primary chamber 2.

 During the outflow of gases from the nozzles of the exhaust channels 1 of the primary chamber 2, the air in the rarefaction chamber 11 intensively enters the primary chamber 2 through the purge channels 8, promoting high-quality combustion of the gas-powder mixture during its secondary expansion and at the same time creating a significant decrease in atmospheric pressure in the chamber 11 rarefaction.

 The gas-air mixture, vigorously moving along the cavity of the expansion chamber 5 from the blades 4, 22 to the left towards the rear wall 9, bypasses the purge holes 10 located on the back (left) side of the tides in the rarefaction zone, through which the remaining air is sucked from the piston cavity of the chamber 11 rarefaction into the expansion chamber 5, which also contributes to the afterburning and partial cooling of the gas-air mixture with the release of additional energy.

 Due to the outflow of air through the purge holes 10 and the purge channels 8, the pressure in the piston chamber of the rarefaction chamber 11 is reduced as much as possible, which favorably affects the complex and vigorous movement of the moving parts of the device forward (to the right).

 The gas-powder mixture without delays and mechanical resistances is freely and fully accepted by the primary chamber 2, expansion chamber 5 and chambers 3, after secondary expansion, having performed a certain part of the mechanical work, it is discarded into the left part of the expansion chamber 5, where in the region of the rear wall 9, due to the total pressure of all chambers 3, a high-pressure zone of the gas-air mixture is created, which on the back wall 9, turning in the direction of the barrel 7, through the bypass windows 12 made in the rear (left) part the cylinder 16, enters the secondary chamber 13, where, having created a high pressure zone on the working surface of the piston 14, informs him, and at the same time of the body of the barrel 7 and, accordingly, the blades 4, 22, a powerful energy pulse with a force vector directed forward ( to the right).

 As a result of the addition of the force vectors obtained from the direct action of the gas-powder and gas-air mixtures on the blades 4, 22 of the primary chamber 2 and chambers 3, as well as on the working surface of the piston 14, a certain part of the recoil momentum is parried due to the forces of the arising reactive moments. the barrel 7 is moved with the piston 14 and the blades 4 rigidly connected to it, as a result of which the return spring 15 is compressed, enclosed between the piston 14 and the front wall 20 made in the front of the cylinder 16, the outer and inner walls which are the inner and outer walls of the expansion chamber 5 and the rarefaction chamber 11, respectively.

 The rear end part of the cylinder 16 is rigidly fixed to the rear end part of the casing 17.

 The movement of the piston 14 with the barrel 7 and the blades 4 continues until the piston stop 18 comes across a buffer chipper 19, rigidly fixed to the inner wall of the front of the cylinder 16, informing the latter, and through it the cylinder 16, the casing 17 and accordingly rigidly the frame 21 of the weapon itself mounted with it, a shock pulse that fights off the remaining part of the recoil of the weapon and the bulk of the reaction of the bullet (projectile).

 The excess part of the pressure of the gas-air mixture is rarefied due to the rapid increase in the volume of the device due to the movement of the piston 14 forward and, accordingly, the equally dynamic increase in the volume of the secondary chamber 13, as well as the discharge of the excess gas-air mixture through the gas outlet channels 1 back to the bore 7, which has a significant below atmospheric due to oxygen burnout and extraction from the bore of the barrel 7 mechanical and molecular particles carried away by the rarefaction zone formed behind the bullet (projectile) , back, in the direction of the chamber, thereby also creating a pulsed reactive moment with a force vector directed forward (to the right).

 The stroke length of the piston 14 and, respectively, of the barrel 7 with blades 4, 22 is selected individually for each type of weapon and is determined by the length of the cartridge (projectile), plus 10% supplied from the store in a straight line in the vertical (horizontal) plane to align the longitudinal axis of the cartridge (projectile) with the longitudinal axis of the bore, while the barrel 7 with blades extends forward, outward, beyond the end of the front edge of the casing 17 so that the blade 4 of the primary chamber 2 extends beyond the end of the casing 17 to a distance equal to the distance between the blades 4.

 The pressure in the internal cavity of the device rapidly drops, and the compressed return spring 15, enclosed between the piston 14, moving together with the barrel 7 and the blades rectilinearly along the axis of the bore 7 and the casing 17, by means of a cylinder 16 rigidly attached to it with the front wall 20 returns all moving details in the starting position.

 In this case, there is ventilation and cooling of all cavities and the bore.

Claims (13)

 1. A device for braking the recoil of small arms, comprising a piston spring-loaded relative to the barrel of the cylinder with a front wall, and a barrel made with gas channels, characterized in that it is provided with a cylindrical casing with a rear wall and a front end, the piston is rigidly connected to the barrel, which has the ability to move relative to the casing, which is connected with the cylinder and covers it and the front part of the barrel protruding from it, which is made with the front gas-dynamic blade and at least one Modes shovel, each vane has a C-shaped radial section with convexity facing towards the outlet of the barrel and forms an annular chamber with a casing, each additional blade has a bypass window and venting channels connect the barrel cavity of the barrel with the respective annular chambers.  2. The device according to claim 1, characterized in that the cylinder has purge holes in the front wall.  3. The device according to claim 1 or 2, characterized in that each of the blades contacts its edges with the casing, and the bypass windows of the additional blades are displaced in the contact zone with the casing.  4. The device according to any one of claims 1 to 3, characterized in that the gas outlet channels of the barrel are directed at an angle to the axis of the barrel with the apex of the angle facing the barrel inlet.  5. The device according to any one of claims 1 to 4, characterized in that the cylinder is made with purge channels in the front wall.  6. The device according to any one of claims 1 to 5, characterized in that the inner surface of the rear wall of the casing has a C-shaped radial section with a bulge facing the barrel inlet. 7. The device according to any one of claims 1 to 6, characterized in that, in the presence of additional blades, each of them has said bypass windows located 90 ^° offset, each annular chamber is connected to the barrel cavity by four indicated gas outlet channels in the zones between the bypass windows, and the bypass windows of adjacent blades are offset from each other by 45 ^o .  8. The device according to any one of claims 1 to 7, characterized in that the axis of each gas outlet channel in radial section is perpendicular to the chord connecting the base of the corresponding blade with the place of its contact with the casing.  9. The device according to any one of paragraphs.2-8, characterized in that the cylinder is made with tides on the outer surface, and each purge hole of the cylinder is located on the inclined surface of the corresponding tide facing the rear wall of the casing.  10. The device according to any one of claims 1 to 9, characterized in that the connection of the cylinder with the casing is made in the form of fastening on the end wall of the casing of the rear end of the cylinder, and the cylinder has overflow windows in the fixing zone.  11. The device according to any one of claims 1 to 10, characterized in that the piston surface facing the rear end wall of the casing is made concave.  12. The device according to any one of paragraphs. 1-11, characterized in that the spring is placed in the cavity of the cylinder between its front wall and the piston.  13. The device according to any one of claims 1 to 12, characterized in that the blades are made circular.

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